JP2009111521A - Video correction device, video correction method, and video correction program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video correction device, a video correction method and a video correction program, which can properly correct digital noise. <P>SOLUTION: The device and method of the invention can correct the digital noise by noise correction amount information according to a digital noise generation amount, and can properly correct the digital noise in the way because the digital noise generation amount of the digital noise included in a video signal can be estimated from a bit rate of coded video data by correcting the digital noise included in the video signal based on noise correction amount information. A video signal is created by decoding of the coded video data which are made by compressing and coding of a television program, a bit rate of the coded video data is obtained, and the noise amount correction information is obtained according to the obtained bit rate from a hard disk drive which stores the noise correction amount information for correction of the digital noise corresponding to the bit rate in the coded video data after the compression and coding. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a video correction device, a video correction method, and a video correction program, and is suitable for application to, for example, a program playback device that plays back a broadcast television program.

  2. Description of the Related Art Conventionally, in a program playback apparatus, a television program that is broadcast via a broadcast wave such as terrestrial digital broadcasting and that is compression-encoded with a predetermined compression-encoding method is received, decoded, and reproduced. What has been made is widespread.

  Although such a television program is compression-encoded using motion compensation to increase the compression rate, the amount of motion in the television program increases or the degree of motion becomes intense. Accordingly, the amount of data tends to increase. Also, television programs tend to increase the amount of data as the images become more precise.

  On the other hand, there is an upper limit on the transmission capacity of a transmission path (for example, an optical fiber) or a transmission medium (for example, a broadcast wave) for transmitting a television program.

  As a result, television programs are compressed and encoded at a higher compression rate to match the transmission capacity as the amount of motion increases or the degree of motion increases, or as the image becomes denser. In some cases, the amount of data is insufficient, and digital noise such as block noise and mosquito noise is generated during decoding.

For this reason, some program playback apparatuses are adapted to correct digital noise generated during decoding of a television program in accordance with a preset fixed noise correction amount during playback (for example, Patent Document 1).
JP 2005-236955 A

  By the way, in general, a television program includes various scenes. Depending on the amount and degree of movement in each scene or the fineness of the screen, the presence or absence of digital noise and its amount (hereinafter referred to as this). (Referred to as digital noise generation amount) varies.

  However, since the above-described program reproduction apparatus corrects digital noise according to a fixed noise correction amount, if the amount of digital noise generated in a television program changes, the digital noise correction may be excessive or insufficient. That is, in the conventional program playback device, when the amount of digital noise generated in a television program changes, there may be a case where digital noise remains without a sufficient amount of noise correction, or there is too much noise correction amount and image quality deteriorates. There was a problem that it was difficult to say that digital noise was properly corrected.

  The present invention has been made in view of the above points, and an object of the present invention is to propose a video correction apparatus, a video correction method, and a video correction program that can appropriately correct digital noise.

  In order to solve such a problem, in the present invention, decoded video content is generated by decoding compressed encoded video data obtained by compressing and encoding video content, the bit rate of the compressed encoded video data is acquired, and the video content Noise corresponding to the bit rate acquired from the correction information storage unit that stores noise correction information for correcting digital noise associated with compression encoding in association with the bit rate in the compressed encoded video data after the compression encoding. Correction information is acquired, and digital noise included in the decoded video content is corrected based on the noise correction information.

  As a result, the digital noise generation amount of the digital noise included in the decoded video content can be estimated from the bit rate of the compressed encoded video data, so that the digital noise can be corrected with the digital noise correction information corresponding to the digital noise generation amount. Can do.

  According to the present invention, since the digital noise generation amount of the digital noise included in the decoded video content can be estimated from the bit rate of the compression encoded video data, the digital noise correction information corresponding to the digital noise generation amount can be used to calculate the digital noise. Thus, it is possible to realize a video correction apparatus, a video correction method, and a video correction program that can appropriately correct digital noise.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

(1) First Embodiment (1-1) Configuration of Program Recording / Reproducing Device According to First Embodiment In FIG. 1, a program recording / reproducing device 1 is broadcast by terrestrial digital television broadcasting or the like (ie, broadcasting). The television program transmitted from the station), which is compressed and encoded by a predetermined compression encoding method, is decoded and reproduced to reproduce the television program. In addition, the user can view the audio. The program recording / reproducing apparatus 1 records (that is, records) the received television program, and decodes and reproduces the recorded television program, whereby the video and audio are transmitted via the external monitor device 2. Can be viewed by the user.

  The program recording / reproducing apparatus 1 is configured to control the whole by a control unit 3. The control unit 3 is configured around a CPU (Central Processing Unit) 4 and reads various programs such as a basic program and a digital noise correction program from a ROM (Read Only Memory) 5 connected via a system bus 7. In addition, digital noise correction processing and the like can be performed by expanding and executing on a RAM (Random Access Memory) 6.

  The program recording / playback apparatus 1 accepts an operation by a user via an operation unit (not shown), and also inputs an infrared signal transmitted from the remote controller 8 when the user operates the remote controller 8 as an input interface. 9 is received through an infrared light receiving unit (not shown), converted into a predetermined operation signal, and supplied to the control unit 3 through the system bus 7. At this time, the control unit 3 executes various processes in accordance with the operation signal.

  For example, when an operation for switching a television broadcasting station to be received, that is, a so-called channel switching operation is performed on the remote controller 8 by the user, the control unit 3 should switch based on an operation signal supplied from the input interface 9. The channel is instructed to the receiving unit 10.

  At this time, the program recording / reproducing apparatus 1 extracts the frequency band corresponding to the channel designated by the control unit 3 from the digital broadcast signal received via the antenna (not shown) by the tuner 11 of the receiving unit 10 and then extracts this. Are demodulated by the demodulator 12 and scrambled by the descrambler 13 and then demultiplexed by the demultiplexer 14 for video data packets PV, audio data packets PA and EPG (Electronic Program Guide). Separated into information packets PE and the like.

  The demultiplexer 14 supplies the video data packet PV of the designated channel to the video decoder 15 and the audio data packet PA to the audio decoder 16, and sends the EPG information packet PE of each channel to the EPG decoder 17.

  The video decoder 15 decodes the compressed and encoded video data (hereinafter referred to as encoded video data) stored in the video data packet PV by, for example, MPEG (Motion Pictures Expert Group) 2-Video system. As a result, a video signal SV is generated and supplied to the video signal processing unit 18.

  The video signal processing unit 18 converts the video signal SV into a predetermined signal format and performs various mixing processes to generate an output video signal SVO, which is connected via a video output terminal (not shown). Output to the monitor device 2. In response to this, the monitor device 2 displays a video based on the output video signal SVO on the display panel 19.

  On the other hand, the audio decoder 16 decodes the compression-encoded audio data (hereinafter referred to as encoded audio data) stored in the audio data packet PA, for example, by decoding the audio data using the MPEG2-Audio method. A signal DA is generated and supplied to the audio signal processing unit 20.

  The audio signal processing unit 20 performs audio signal processing such as D / A (Digital Analog) conversion and equalizing on the digital audio signal DA to generate an analog output audio signal SA, which is output to an audio output terminal (not shown). Is output to the monitor device 2 connected via the. In response to this, the monitor device 2 emits sound based on the output sound signal SA from the speaker 21.

  Further, the EPG decoder 17 acquires EPG information such as a broadcast station, a time zone, a genre, and a title of the television program from the EPG information packet PE, and sends these to the hard disk drive interface (HDD I / F) 22, The EPG information is stored in an EPG database configured in the hard disk drive (HDD) 23.

  By the way, when the control unit 3 receives an instruction to record a broadcast television program from the user via the remote controller 8, the control unit 3 receives various packets such as the video data packet PV and the audio data packet PA via the system bus 7. Supplied to the hard disk drive interface 22.

  In response to this, the hard disk drive interface 22 stores the encoded video data extracted from the video data packet PV and the encoded audio data extracted from the audio data packet PA in a file with a title included in the EPG information. In this way, the television program is recorded (that is, recorded) by being sequentially recorded on the hard disk drive 23. Hereinafter, the television program recorded in this way is referred to as a recorded program.

  The control unit 3 also creates a management database for managing recorded programs recorded in the hard disk drive 23. For example, when the control unit 3 receives an instruction to display a list of recorded programs recorded in the hard disk drive 23 from the user via the remote controller 8, the control unit 3 reads the contents of the management database and supplies them to the video signal processing unit 18. As a result, a list display screen of recorded programs is generated and displayed on the display panel 19 of the monitor device 2.

  Here, when a recorded program on the list display screen is selected, the control unit 3 starts reproduction of the recorded program. That is, the control unit 3 reads out the encoded video data from the recorded program file recorded in the hard disk drive 23 and supplies the encoded video data to the video decoder 15, and reads out the encoded audio data and supplies it to the audio decoder 16.

  After that, the control unit 3 generates the output video signal SVO by the video decoder 15 and the video signal processing unit 18 and receives the output video signal SVO by the audio decoder 16 and the audio signal processing unit 20 in the same manner as when receiving the broadcast television program. By generating the output audio signal SA and supplying the output video signal SVO and the output audio signal SA to the monitor device 2, the recorded program is played back and viewed by the user.

  In this way, the program recording / playback apparatus 1 receives the television program being broadcast, causes the user to view the television program via the external monitor device 2, and records the television program on the hard disk drive 23. Thus, a recorded program can be obtained, or the recorded program can be read from the hard disk drive 23 and reproduced.

(1-2) Digital Noise By the way, when a television program being recorded or a recorded program (hereinafter collectively referred to simply as a television program) is decoded by the video decoder 15, block noise or mosquito is detected. Digital noise such as noise may occur.

  Here, block noise and mosquito noise will be described.

  In the MPEG2-Video system, a television program video (that is, a series of continuous images for each frame or field) is divided into rectangular blocks of 8 × 8 pixels, for example, and discrete cosine transform is performed in units of the rectangular blocks. Thus, compression encoding is performed.

  In the MPEG2-Video system, the amount of data is reduced by performing a discrete cosine transform so that the frequency components after conversion are concentrated on the low frequency components (that is, the high frequency components are discarded) during compression encoding. Irreversibly compressed).

  The high frequency component in this discrete cosine transform has a relatively large amount of information in a portion having a large difference in color tone or luminance within a rectangular block, such as the contour of an object. A video that has been irreversibly compression-encoded by being truncated may cause noise such as mosquitoes flying around the outline of an object when decoded. This is mosquito noise.

  Further, in the MPEG2-Video system, when irreversibly compressing and encoding a video, there is no exchange of information regarding the compression encoding between adjacent rectangular blocks. In some cases, the boundary between adjacent rectangular blocks may be manifested as noise in units of n × n rectangular blocks. This is block noise.

  This block noise becomes more apparent when a television program having a predetermined resolution is compressed and encoded at a higher compression rate (that is, the bit rate of the television program is smaller). (That is, “n” in “n × n” increases) (hereinafter referred to as a bit rate versus block number relationship). Therefore, the program recording / reproducing apparatus 1 uses this bit rate vs. block number relationship, and block noise is generated from the bit rate and resolution of a television program among the boundaries between rectangular blocks constituting the video of the television program. A boundary that may occur can be specified in advance.

  Also, digital noise such as block noise and mosquito noise has a relationship in which the generation amount (that is, digital noise generation amount) increases as the bit rate decreases in a television program having a predetermined resolution (hereinafter referred to as bit rate vs. bit rate). This is called noise generation relationship). Therefore, the program recording / reproducing apparatus 1 can estimate how much digital noise is generated (that is, the amount of generated digital noise) from the bit rate and resolution by using this bit rate versus noise generation relationship.

  Digital noise such as block noise and mosquito noise is a major factor that degrades the video (ie, image quality) of a television program.

  Therefore, the program recording / reproducing apparatus 1 is adapted to correct digital noise generated when a television program is decoded.

(1-3) Digital Noise Correction First, as shown in FIG. 2, the video decoder 15 of the program recording / playback apparatus 1 encodes video data obtained from a video data packet PV as a result of receiving a television program being played back. When decoding the MD, or when decoding the encoded video data MD given from the hard disk drive 23 as a result of giving an instruction from the user to reproduce the recorded program, the encoded video data MD and the encoding The video signal SV as a result of decoding the video data MD is supplied to the digital noise detector 24.

  Here, the digital noise detection unit 24 includes a bit rate acquisition unit 24A that acquires the bit rate of the television program, a resolution acquisition unit 24B that acquires the resolution of the television program, and noise that detects the position where the digital noise occurs. The position detection unit 24C is configured.

  The bit rate acquisition unit 24A of the digital noise detection unit 24 measures the data amount per unit time of the encoded video data MD, and thereby the bit rate BR of the encoded video data MD (for example, the bit rate for each rectangular block). Is supplied to the noise position detection unit 24C. Incidentally, the bit rate acquisition unit 24A continuously acquires the bit rate BR and detects the noise position while the encoded video data MD is supplied from the video decoder 15 (that is, while the television program is played back). It is made to supply to the part 24C.

  Further, the resolution acquisition unit 24B of the digital noise detection unit 24 analyzes the video signal SV, so that the resolution of the video signal SV is, for example, a resolution (640 × 480, etc.) according to SDTV (Standard Definition Television). It is determined whether the resolution (1920 × 1080 or the like) according to HDTV (High Definition Television) is obtained, and resolution information DI as a determination result is acquired. Then, the resolution acquisition unit 24B supplies the resolution information DI to the noise position detection unit 24C.

  When the bit position BR and the resolution information DI are given, the noise position detection unit 24C is generated when the television program (that is, the encoded video data MD) is decoded by using the above-described bit rate versus noise generation relationship. Then, the estimated amount of digital noise (that is, the amount of digital noise generated) is estimated.

  The noise position detector 24C is information for correcting the digital noise of the estimated digital noise generation amount without excess or deficiency (that is, information indicating a correction amount capable of correcting the generated digital noise, and hereinafter referred to as noise). NR) is acquired.

  This noise correction amount information NR is, for example, information including a threshold value that defines a difference in luminance between RGB (red, green, and blue) between adjacent pixels in a video that constitutes a television program. When a luminance difference exceeding a threshold value indicated by the information NR is detected, the luminance difference is information for specifying digital noise to be corrected. The noise correction amount information NR includes a block noise threshold (hereinafter also referred to as a block noise correction threshold) and a mosquito noise threshold (hereinafter also referred to as a mosquito noise correction threshold). And

  The noise correction amount information NR is stored in the hard disk drive 23.

  Specifically, the noise correction amount information NR is stored in the hard disk drive 23 so as to be stored in a database associated with the bit rate BR (hereinafter referred to as a noise correction amount database). Further, the noise correction amount database is prepared for each resolution of the television program.

  As a result, the noise position detection unit 24C of the digital noise detection unit 24 acquires the noise correction amount information NR corresponding to the digital noise generation amount from the noise correction amount database of the hard disk drive 23.

  The noise position detection unit 24C then detects a position where digital noise is generated in the video signal SV supplied from the video decoder 15 in accordance with the bit rate BR, resolution information DI, and noise correction amount information NR (hereinafter referred to as noise generation position). NPs are detected sequentially.

  Specifically, first, the noise position detection unit 24C uses the above-described relationship between the bit rate and the number of blocks, and according to the bit rate BR and the resolution information DI, between the rectangular blocks on the video corresponding to the video signal SV. Among boundaries, identify boundaries where block noise may occur.

  Next, the noise position detection unit 24 </ b> C detects a luminance difference value between RGB (red, green, and blue) between adjacent pixels across the specified boundary (hereinafter, referred to as a luminance difference value), and the luminance difference The value is compared with the block noise correction threshold value indicated by the noise correction amount information NR.

  Then, the noise position detection unit 24C determines the position where the block noise is generated (that is, the noise related to the block noise) from the boundary of the luminance difference value exceeding the block noise correction threshold value of the noise correction amount information NR. This is detected as the generation position NP).

  On the other hand, the noise position detection unit 24C calculates the luminance difference values of RGB (red, green, and blue) between pixels adjacent in the vertical direction and the horizontal direction in each of a plurality of rectangular blocks that form a video corresponding to the video signal SV. The brightness difference value is compared with the mosquito noise correction threshold value of the noise correction amount information NR.

  Then, the noise position detection unit 24C converts a rectangular block having a pixel having a luminance difference value exceeding the mosquito noise correction threshold value of the noise correction amount information NR out of the plurality of rectangular blocks constituting the video according to the video signal SV. It is detected as a position where noise is generated (that is, a noise generation position NP related to mosquito noise).

  When the noise position detection unit 24C detects the noise generation position NP in this manner, the noise position detection unit NP supplies the noise generation position NP together with the noise correction amount information NR to the video signal processing unit 18.

  When the noise generation position NP and the noise correction amount information NR are supplied from the noise position detection unit 24C of the digital noise detection unit 24, the video signal processing unit 18 performs a noise generation position when performing various mixing processes on the video signal SV. Occurs when decoding the video signal SV by correcting the luminance of each pixel so that the luminance difference value (that is, digital noise) exceeding the threshold value indicated by the noise correction amount information NR does not appear at the position indicated by the NP. The output video signal SVO is generated by correcting the digital noise.

  Specifically, when the video signal processing unit 18 performs various kinds of mixing processing on the video signal SV, the noise correction amount information is obtained by using, for example, a predetermined coefficient or function at the boundary between the rectangular blocks indicated by the noise generation position NP. The luminance of pixels having a luminance difference value exceeding the block noise correction threshold indicated by NR is averaged with the luminance of surrounding pixels, and correction is performed so that block noise does not appear.

  In addition, when the video signal processing unit 18 performs various mixing processes on the video signal SV, the mosquito indicated by the noise correction amount information NR is used by using, for example, a predetermined coefficient or function in the rectangular block indicated by the noise generation position NP. The luminance of pixels having a luminance difference value exceeding the noise correction threshold is averaged with the luminance of surrounding pixels, and correction is performed so that mosquito noise does not appear.

  Thus, the program recording / reproducing apparatus 1 can detect the bit rate BR of the television program and estimate the digital noise generation amount from the bit rate BR. As a result, the noise correction according to the digital noise generation amount can be performed. The quantity information NR is acquired and digital noise is corrected.

(1-4) Processing Procedure Next, processing in which the program recording / playback apparatus 1 corrects digital noise in the first embodiment will be described with reference to the flowchart of FIG.

  Actually, when starting the reproduction of the television program, the control unit 3 of the program recording / reproducing apparatus 1 starts the digital noise correction processing procedure RT1 and proceeds to step SP1.

  In step SP1, the control unit 3 uses the video decoder 15 to decode the encoded video data MD to generate the video signal SV, and proceeds to the next step SP2.

  In step SP2, the control unit 3 uses the bit rate acquisition unit 24A of the digital noise detection unit 24 to measure the data amount per unit time of the encoded video data MD, thereby determining the bit rate BR of the encoded video data MD. get. Further, the control unit 3 acquires the resolution information DI by analyzing the video signal SV by the resolution acquisition unit 24B of the digital noise detection unit 24, and proceeds to the next step SP3.

  In step SP3, the control unit 3 estimates the digital noise generation amount from the bit rate BR and the resolution information DI by the noise position detection unit 24C of the digital noise detection unit 24. Then, the control unit 3 acquires the noise correction amount information NR corresponding to the digital noise generation amount from the hard disk drive 23, and proceeds to the next step SP4.

  In step SP4, the control unit 3 uses the noise position detection unit 24C of the digital noise detection unit 24 to generate a noise generation position where digital noise is generated in the video signal SV according to the bit rate BR, resolution information DI, and noise correction amount information NR. NP is sequentially detected, and the process proceeds to the next step SP5.

  In step SP5, the control unit 3 corrects digital noise generated at the time of decoding the video signal SV by the video signal processing unit 18 according to the noise generation position NP and the noise correction amount information NR, and outputs the output video signal SVO. Generate and move to next step SP6.

  In step SP6, the control unit 3 determines whether or not to end the reproduction of the television program. If a negative result is obtained here, this means that the user is continuously watching the television program being broadcast or the recorded program. At this time, the control unit 3 again executes step SP2. Return to.

  On the other hand, if an affirmative result is obtained in step SP6, this means that the user has finished watching the television program being recorded or the recorded program. At this time, the control unit 3 performs the next step. Moving to SP7, the digital noise correction processing procedure RT1 is terminated.

  By such digital noise correction processing procedure RT1, the program recording / reproducing apparatus 1 in the first embodiment corrects digital noise of a television program.

(1-5) Operation and Effect in First Example In the above configuration, the control unit 3 of the program recording / playback apparatus 1 measures the data amount per unit time of the encoded video data MD by the bit rate acquisition unit 24A. Thus, the bit rate BR of the encoded video data MD is acquired, and the resolution information DI is acquired by analyzing the video signal SV by the resolution acquisition unit 24B.

  The control unit 3 of the program recording / playback apparatus 1 is predicted to occur when the noise position detection unit 24C decodes a television program (that is, encoded video data MD) according to the bit rate BR and the resolution information DI. The amount of digital noise generated is estimated.

  Further, the control unit 3 of the program recording / playback apparatus 1 acquires the noise correction amount information NR corresponding to the digital noise generation amount from the hard disk drive 23 by the noise position detection unit 24C.

  Further, the control unit 3 of the program recording / playback apparatus 1 uses the noise position detection unit 24C to determine the noise generation position NP where the digital noise is generated in the video signal SV according to the bit rate BR, the resolution information DI, and the noise correction amount information NR. To detect.

  Then, the control unit 3 of the program recording / playback apparatus 1 corrects digital noise generated when the video signal SV is decoded by the video signal processing unit 18 according to the noise generation position NP and the noise correction amount information NR.

  Therefore, the program recording / reproducing apparatus 1 estimates the digital noise generation amount from the bit rate BR of the television program during the reproduction of the television program having a predetermined resolution, and the noise correction amount information NR corresponding to the digital noise generation amount. Therefore, the digital noise can be corrected after specifying the noise generation position NP where the digital noise is likely to occur in the video signal SV.

  As a result, the program recording / reproducing apparatus 1 corrects only the noise generation position NP in the video signal SV and does not correct positions other than the noise generation position NP (that is, positions determined not to generate digital noise). The digital noise can be appropriately corrected with the noise correction amount information NR corresponding to the amount of digital noise generation without causing the digital noise to remain or to be corrected too much and the image quality to deteriorate.

  Further, the program recording / reproducing apparatus 1 acquires the resolution information DI by analyzing the video signal SV, and acquires the noise correction amount information NR not only according to the bit rate BR but also the resolution information DI.

  Therefore, the program recording / reproducing apparatus 1 can estimate the digital noise generation amount according to not only the bit rate BR of the television program but also the resolution information DI during the reproduction of the television program having a predetermined resolution. It can correct more appropriately.

  In other words, the program recording / playback apparatus 1 has, for example, an SDTV image quality even when a television program being played or a recorded program has SDTV image quality and HDTV image quality of different resolutions mixed. Since it is possible to avoid the situation where the digital noise of the video is corrected with the noise correction amount information NR and the noise generation position NP of the HDTV image quality, the digital noise can be corrected more appropriately.

  Furthermore, since the program recording / reproducing apparatus 1 switches the noise correction amount information NR used when specifying the noise occurrence position NP according to the bit rate BR and the resolution information DI, the noise is detected using only the fixed noise correction amount information NR. Compared with the case where the generation position NP is specified, the accuracy of specifying the noise generation position NP (that is, the detection accuracy of digital noise) can be improved.

  According to the above configuration, the program recording / playback apparatus 1 generates the video signal SV by decoding the encoded video data MD obtained by compressing and encoding the television program, and acquires the bit rate BR of the encoded video data MD. Noise correction of the hard disk drive 23 that stores noise correction amount information NR for correcting digital noise accompanying compression encoding of a television program in association with the bit rate BR in the encoded video data MD after the compression encoding The noise correction amount information NR corresponding to the acquired bit rate BR is acquired from the amount database, and the digital noise included in the video signal SV is corrected based on the noise correction amount information NR. From the bit rate BR of the video data MD, the digital noise of the digital noise included in the video signal SV is calculated. It can be estimated to FIG generation amount, it is possible to correct the digital noise in the noise correction amount information NR corresponding to the digital noise amount, thus it is possible to properly correct the digital noise.

(2) Second Embodiment Next, digital noise correction in the second embodiment will be described.

(2-1) Configuration of Program Recording / Reproducing Device According to Second Embodiment A program recording / reproducing device 1 according to the second embodiment is a program recording / reproducing device 1 according to the first embodiment described above (FIG. 1). However, the digital noise correction method is different from that of the program recording / playback apparatus 1 in the first embodiment.

  More specifically, the program recording / playback apparatus 1 of the first embodiment constantly detects the bit rate BR of the television program, whereas the program recording / playback apparatus 1 of the second embodiment The bit rate BR of the program is acquired for each television program.

  The program recording / reproducing apparatus 1 in the second embodiment accumulates the bit rate BR (hereinafter referred to as program bit rate PBR) obtained in this way for each television program, and the accumulated program bit rate. Digital noise is corrected using PBR.

  Therefore, hereinafter, only the accumulation of the program bit rate PBR and the correction of digital noise will be described, and the configuration of the program recording / playback apparatus 1 will be referred to the first embodiment.

(2-2) Accumulation of Program Bit Rate Using EPG Information As shown in FIG. 4, the bit rate acquisition unit 24A of the digital noise detection unit 24 sends the broadcast television program received by the reception unit 10 to the user. When viewing, the amount of encoded video data MD per unit time (that is, bit rate BR) is acquired at predetermined time intervals (for example, about 5 minutes) and averaged from the start to the end of the television program. Thus, the average bit rate BR of the television program being broadcast (that is, the program bit rate PBR in units of the television program) is acquired.

  At this time, the resolution acquisition unit 24B of the digital noise detection unit 24 acquires the resolution information DI by analyzing the video signal SV as described above in the first embodiment.

  The digital noise detector 24 supplies the EPG decoder 17 with the program bit rate PBR and resolution information DI acquired in this way.

  On the other hand, when the EPG decoder 17 of the program recording / playback apparatus 1 allows the user to view the broadcast television program received by the receiving unit 10, the EPG decoder 17 converts the television program from the EPG information packet PE as described above. EPG information EI such as broadcasting station, time zone, genre, title, etc. is acquired.

  The EPG decoder 17 stores the program bit rate PBR and the resolution information DI in an EPG database configured in the hard disk drive 23 so as to be associated with the EPG information EI.

  Here, as shown in FIG. 5, the EPG database DB includes a database (hereinafter referred to as an overall database) DB1 that accumulates averages of program bit rates PBR of the entire television programs of a predetermined broadcast station, and a predetermined broadcast. DB2 for storing the average of program bit rate PBR for each station time zone (hereinafter referred to as time zone database) DB2 and database for storing program bit rate PBR for each genre of television program of a predetermined broadcasting station DB 3 (hereinafter referred to as a genre database), a database (hereinafter referred to as a title database) DB 4 for storing program bit rate PBR for each title of a television program of a predetermined broadcast station, and a predetermined broadcast station Program bit rate PBR for each TV program time zone and title Database for product and a (hereinafter, this is referred to as time zone title database) DB 5 Metropolitan.

  In this overall database DB1, the average of program bit rates PBR of television programs that have been viewed so far at a predetermined broadcasting station (hereinafter referred to as average bit rate ABR) is aggregated for each resolution information DI, and is subject to aggregation. Are stored for each resolution information DI together with the number of television programs (hereinafter referred to as the number of viewing programs).

  In the time zone database DB2, for example, the average bit rate ABR for each time zone such as “17:00 to 18:00” or “18:00 to 19:00” is classified and aggregated for each resolution information DI. These are stored together with the number of viewing programs of the television programs to be counted.

  Furthermore, in the genre database DB3, for example, the average bit rate ABR for each genre such as “news”, “drama”, “sports”, and “animation” is classified and totaled for each resolution information DI, and becomes the target of aggregation. It is stored together with the number of viewing programs of the television program.

  Further, in the title database DB4, for example, the average bit rate ABR for each title of a television program such as “News XYZ” or “Weather Forecast EX” is classified and aggregated for each resolution information DI, and the television subject to aggregation is recorded. It is stored together with the number of programs viewed by John.

  Further, in the time zone title database DB5, for example, “news XYZ” in the time zone “22:00 to 23:00”, the time zone of the television program and the average bit rate ABR for each title are set for each resolution information DI. And is stored together with the number of viewing programs of the television programs that have been counted.

  The entire database DB1, the time zone database DB2, the genre database DB3, the title database DB4, and the time zone title database DB5 are prepared for each broadcasting station.

  Therefore, the EPG decoder 17 determines, for example, “broadcast station: A”, “time zone: 18: 00-19: 00”, “genre: news”, and “title: news XYZ” from the currently broadcast television program. When such EPG information EI (FIG. 5) is acquired, the program bit rate PBR for each resolution information DI is stored (that is, accumulated) in the EPG database DB of the broadcasting station A so as to be associated with the EPG information EI. .

  Specifically, the EPG decoder 17 responds to the fact that “Broadcasting station: A” is indicated in the EPG information EI, and the average bit rate ABR and the number of viewing programs according to the resolution information DI from the entire database DB1 of the broadcasting station A. Is read.

  The EPG decoder 17 newly recalculates the average bit rate ABR by dividing the value obtained by adding the program bit rate PBR to the integrated value of the average bit rate ABR and the number of viewing programs by the number of viewing programs + 1. Further, the EPG decoder 17 sets the number of viewing programs + 1 as the new number of viewing programs. The EPG decoder 17 stores the new average bit rate ABR and the number of viewing programs so as to overwrite the entire database DB1 in accordance with the resolution information DI, thereby accumulating the program bit rate PBR in the entire database DB1. To do.

  Incidentally, in the overall database DB1, even if the program bit rate PBR has never been accumulated, as a default setting of the program recording / playback apparatus 1, a predetermined average bit rate ABR and the number of viewing programs (that is, “1”) is stored in advance.

  Further, the EPG decoder 17 reads “time zone: 18:00 to 19:19 from the time zone database DB2 of the broadcasting station A in response to the fact that“ time zone: 18:00 to 19:00 ”is indicated in the EPG information EI. 00 ”and the average bit rate ABR and the number of viewing programs corresponding to the resolution information DI are read out.

  The EPG decoder 17 newly recalculates the average bit rate ABR by dividing the value obtained by adding the program bit rate PBR to the integrated value of the average bit rate ABR and the number of viewing programs by the number of viewing programs + 1. Further, the EPG decoder 17 sets the number of viewing programs + 1 as the new number of viewing programs. Then, the EPG decoder 17 stores these new average bit rate ABR and the number of viewing programs so as to overwrite the time zone database DB2 in accordance with “time zone: 18:00 to 19:00” and resolution information DI. Thus, the program bit rate PBR is stored in the time zone database DB2.

  Further, the EPG decoder 17 views the average bit rate ABR according to “genre: news” and resolution information DI from the genre database DB3 of the broadcasting station A in response to the fact that “genre: news” is indicated in the EPG information EI. Read the number of programs.

  The EPG decoder 17 newly recalculates the average bit rate ABR by dividing the value obtained by adding the program bit rate PBR to the integrated value of the average bit rate ABR and the number of viewing programs by the number of viewing programs + 1. Further, the EPG decoder 17 sets the number of viewing programs + 1 as the new number of viewing programs. Then, the EPG decoder 17 stores the new average bit rate ABR and the number of viewing programs so as to overwrite the genre database DB3 in accordance with “genre: news” and resolution information DI, so that the genre database DB3 is stored. The program bit rate PBR is stored.

  Further, the EPG decoder 17 responds to the fact that “title: news XYZ” is indicated in the EPG information EI, from the title database DB 4 of the broadcasting station A, and the average bit rate ABR according to the resolution information DI. And the number of viewing programs are read out.

  The EPG decoder 17 newly recalculates the average bit rate ABR by dividing the value obtained by adding the program bit rate PBR to the integrated value of the average bit rate ABR and the number of viewing programs by the number of viewing programs + 1. Further, the EPG decoder 17 sets the number of viewing programs + 1 as the new number of viewing programs. Then, the EPG decoder 17 stores the new average bit rate ABR and the number of viewing programs so as to overwrite the title database DB4 in accordance with “title: news XYZ” and resolution information DI. To store the program bit rate PBR.

  Further, the EPG decoder 17 reads “time” from the time zone title database DB5 of the broadcasting station A in response to “time zone: 18:00 to 19:00” and “title: news XYZ” shown in the EPG information EI. Band: 18: 00-19: 00 ”,“ Title: News XYZ ”, and average bit rate ABR and the number of viewing programs according to resolution information DI are read.

  The EPG decoder 17 newly recalculates the average bit rate ABR by dividing the value obtained by adding the program bit rate PBR to the integrated value of the average bit rate ABR and the number of viewing programs by the number of viewing programs + 1. Further, the EPG decoder 17 sets the number of viewing programs + 1 as the new number of viewing programs. Then, the EPG decoder 17 sets the new average bit rate ABR and the number of programs to be viewed according to the “time zone: 18:00 to 19:00”, “title: news XYZ”, and resolution information DI, the time zone title database DB5. The program bit rate PBR is accumulated in the time zone title database DB5.

  Incidentally, when the program bit rate PBR has never been stored in the time zone database DB2, the genre database DB3, the title database DB4, and the time zone title database DB5, the EPG decoder 17 In the database DB2, the genre database DB3, the title database DB4, and the time zone title database DB5, the program bit rate PBR corresponding to the EPG information EI is stored as it is as the average bit rate ABR, and “1” is stored as the number of viewing programs. By doing so, the program bit rate PBR is accumulated.

  In this way, when the program recording / playback apparatus 1 allows a user to view a broadcast television program, the program bit rate PBR of the television program is stored in the EPG database DB of the hard disk drive 23 in association with the EPG information EI. (Ie, updating the average bit rate ABR). Hereinafter, the process of accumulating the program bit rate PBR every time the television program is viewed is referred to as a bit rate accumulation process.

(2-3) Digital Noise Correction Next, digital generated at the time of decoding a television program using the program bit rate PBR (that is, average bit rate ABR) stored in the EPG database DB of the hard disk drive 23. A method for correcting noise will be described.

  The program recording / reproducing apparatus 1 performs digital noise correction processing for correcting digital noise in parallel with the above-described bit rate accumulation processing when the user watches a television program being broadcast.

  The EPG decoder 17 of the program recording / playback apparatus 1 acquires the EPG information EI from the EPG information packet PE as part of the above-described bit rate accumulation processing, and also receives the resolution information DI from the resolution acquisition unit 24B of the digital noise detection unit 24. Upon acquisition, in the digital noise correction process, the average bit rate ABR and noise correction amount information NR corresponding to the EPG information EI and resolution information DI are acquired from the hard disk drive 23.

  Specifically, the EPG decoder 17 includes, for example, EPG information EI and resolution such as “broadcast station: A”, “time zone: 18:00 to 19:00”, “genre: news”, and “title: news XYZ”. When the information DI is acquired, first, the average bit rate ABR corresponding to “time zone: 18:00 to 19:00” and “title: news XYZ” is determined according to the resolution information DI. Search from.

  When the EPG decoder 17 detects the average bit rate ABR corresponding to “time zone: 18:00 to 19:00” and “title: news XYZ” from the time zone title database DB5, the EPG decoder 17 determines the average bit rate ABR. get. Further, the EPG decoder 17 acquires the noise correction amount information NR corresponding to the average bit rate ABR and the resolution information DI from the noise correction amount database.

  On the other hand, when the EPG decoder 17 cannot detect the average bit rate ABR corresponding to “time zone: 18:00 to 19:00” and “title: news XYZ” from the time zone title database DB5, In addition, the average bit rate ABR corresponding to “title: news XYZ” is searched from the title database DB 4 according to the resolution information DI.

  When the EPG decoder 17 detects the average bit rate ABR corresponding to “title: news XYZ” from the title database DB4, the EPG decoder 17 acquires the average bit rate ABR. Further, the EPG decoder 17 acquires the noise correction amount information NR corresponding to the average bit rate ABR and the resolution information DI from the noise correction amount database.

  On the other hand, when the average bit rate ABR corresponding to “title: news XYZ” cannot be detected from the title database DB4, the EPG decoder 17 next calculates the average bit rate ABR corresponding to “genre: news”. The genre database DB3 is searched according to the resolution information DI.

  When the EPG decoder 17 detects the average bit rate ABR corresponding to “genre: news” from the genre database DB3, the EPG decoder 17 acquires the average bit rate ABR. Further, the EPG decoder 17 acquires the noise correction amount information NR corresponding to the average bit rate ABR and the resolution information DI from the noise correction amount database.

  On the other hand, if the average bit rate ABR corresponding to “genre: news” cannot be detected from the genre database DB3, the EPG decoder 17 next corresponds to “time zone: 18:00 to 19:00”. The average bit rate ABR is searched from the time zone database DB2 according to the resolution information DI.

  When the EPG decoder 17 detects the average bit rate ABR corresponding to “time zone: 18:00 to 19:00” from the time zone database DB2, the EPG decoder 17 acquires the average bit rate ABR. Further, the EPG decoder 17 acquires the noise correction amount information NR corresponding to the average bit rate ABR and the resolution information DI from the noise correction amount database.

  On the other hand, when the average bit rate ABR corresponding to “time zone: 18:00 to 19:00” cannot be detected from the time zone database DB2, the EPG decoder 17 finally sets “broadcast station: A”. The corresponding average bit rate ABR is acquired from the entire database DB1 according to the resolution information DI.

  In this way, the EPG decoder 17 uses the EPG database DB (in this case, the entire database DB1 and the time zone database DB2) of the hard disk drive 23 for the average bit rate ABR corresponding to the EPG information EI and the resolution information DI in the digital noise correction processing. , Genre database DB3, title database DB4, and time zone title database DB5).

  When the EPG decoder 17 obtains the average bit rate ABR, it is predicted that the EPG decoder 17 is generated when the television program is decoded from the average bit rate ABR and the resolution information DI by using the above-described bit rate / noise generation relationship. The amount of digital noise generated is estimated.

  Then, the EPG decoder 17 acquires noise correction amount information NR for correcting the digital noise of the estimated digital noise generation amount from the noise correction amount database of the hard disk drive 23, and this noise correction amount information NR together with the average bit rate ABR. This is supplied to the digital noise detector 24.

  The noise position detection unit 24C of the digital noise detection unit 24 uses the average bit rate ABR and noise correction amount information NR supplied from the EPG decoder 17 and the resolution acquisition unit 24B in the same manner as in the first embodiment described above. In accordance with the acquired resolution information DI, the noise generation position NP where the digital noise is generated in the video signal SV supplied from the video decoder 15 is sequentially detected.

  The noise position detection unit 24C supplies the noise generation position NP detected in this way to the video signal processing unit 18 together with the noise correction amount information NR.

  When the noise generation position NP and the noise correction amount information NR are supplied from the noise position detection unit 24C of the digital noise detection unit 24, the video signal processing unit 18 performs a video signal in the same manner as in the first embodiment described above. An output video signal SVO is generated by correcting digital noise generated during SV decoding.

  As described above, the program recording / playback apparatus 1 stores the program bit rate PBR for each television program in the database as the average bit rate ABR according to the EPG information EI of the television program, and also stores the average bit thus stored. By using the rate ABR, it is possible to estimate the digital noise generation amount of the currently broadcast television program, and as a result, the noise correction amount information NR corresponding to the digital noise generation amount is acquired to correct the digital noise. It is made to do.

(2-4) Processing Procedure Next, processing in which the program recording / playback apparatus 1 corrects digital noise in the second embodiment will be described with reference to the flowcharts of FIGS.

  In practice, when starting the reproduction of the television program being broadcast, the control unit 3 of the program recording / playback apparatus 1 starts the digital noise correction processing procedure RT2 and proceeds to step SP11 (FIG. 6).

  In step SP11, the control unit 3 acquires the EPG information EI from the EPG information packet PE by the EPG decoder 17, and also acquires the resolution information DI through the video decoder 15 and the digital noise detection unit 24, and proceeds to the next step SP12. Move.

  In step SP12, the control unit 3 causes the EPG decoder 17 to store the average bit rate ABR corresponding to the EPG information EI (in this case, broadcasting station, time zone and title) and the resolution information DI in the time zone title database DB5. It is determined whether or not. If a positive result is obtained here, this means that the average bit rate ABR corresponding to the EPG information EI (broadcast station, time zone and title) and the resolution information DI can be obtained from the time zone title database DB5. At this time, the controller 3 proceeds to step SP13.

  In step SP13, the control unit 3 acquires the average bit rate ABR, and proceeds to step SP18 (FIG. 7).

  On the other hand, if a negative result is obtained in step SP12 (FIG. 6), this means that the average bit rate ABR corresponding to the EPG information EI (broadcast station, time zone and title) and the resolution information DI is obtained as the time zone title database DB5. In this case, the control unit 3 proceeds to the next step SP14.

  In step SP14, the control unit 3 determines whether or not the EPG decoder 17 stores the average bit rate ABR corresponding to the EPG information EI (in this case, broadcast station and title) and the resolution information DI in the title database DB4. To do. If a positive result is obtained here, this means that the average bit rate ABR corresponding to the EPG information EI (broadcast station and title) and the resolution information DI can be acquired from the title database DB4. 3 moves to step SP13.

  On the other hand, if a negative result is obtained in step SP14, this indicates that the average bit rate ABR corresponding to the EPG information EI (broadcast station and title) and the resolution information DI cannot be acquired from the title database DB4. At this time, the control unit 3 moves to the next step SP15.

  In step SP15, the control unit 3 determines whether or not the EPG decoder 17 stores the average bit rate ABR corresponding to the EPG information EI (in this case, broadcast station and genre) and the resolution information DI in the genre database DB3. To do. If a positive result is obtained here, this means that the average bit rate ABR corresponding to the EPG information EI (broadcast station and genre) and the resolution information DI can be acquired from the genre database DB3. 3 moves to step SP13.

  On the other hand, if a negative result is obtained in step SP15, this indicates that the average bit rate ABR corresponding to the EPG information EI (broadcast station and genre) and the resolution information DI cannot be acquired from the genre database DB3. At this time, the control unit 3 moves to the next step SP16.

  In step SP16, the control unit 3 uses the EPG decoder 17 to store the average bit rate ABR corresponding to the EPG information EI (in this case, the broadcasting station and the time zone) and the resolution information DI in the time zone database DB2. Determine. If a positive result is obtained here, this means that the average bit rate ABR corresponding to the EPG information EI (broadcast station and time zone) and the resolution information DI can be obtained from the time zone database DB2. The control unit 3 moves to step SP13.

  On the other hand, if a negative result is obtained in step SP16, this indicates that the average bit rate ABR corresponding to the EPG information EI (broadcast station and time zone) and the resolution information DI cannot be obtained from the time zone database DB2. At this time, the controller 3 proceeds to the next step SP17.

  In step SP17, the control unit 3 uses the EPG decoder 17 to obtain the average bit rate ABR corresponding to the EPG information EI (in this case, a broadcasting station) and the resolution information DI from the entire database DB1, and then performs the next step SP18 (FIG. 7). )

  In step SP18, the control unit 3 uses the EPG decoder 17 to estimate the digital noise generation amount from the average bit rate ABR and the resolution information DI. Then, the control unit 3 acquires the noise correction amount information NR corresponding to the digital noise generation amount from the hard disk drive 23, and proceeds to the next step SP19.

  In step SP19, the control unit 3 causes the noise position detection unit 24C of the digital noise detection unit 24 to generate noise in which digital noise is generated in the video signal SV according to the average bit rate ABR, resolution information DI, and noise correction amount information NR. The position NP is sequentially detected, and the process proceeds to the next step SP20.

  In step SP20, the control unit 3 uses the video signal processing unit 18 to correct the digital noise generated when the video signal SV is decoded in accordance with the noise generation position NP and the noise correction amount information NR, thereby generating the output video signal SVO. Generate and move to next step SP21.

  In step SP21, the control unit 3 determines whether or not the broadcasting station of the television program being broadcast has been switched, that is, whether or not the channel has been switched. If an affirmative result is obtained here, this indicates that the channel of the television program being broadcast has been switched, and at this time the control unit 3 returns to step SP11 (FIG. 6) again.

  On the other hand, when an affirmative result is obtained in step SP21 (FIG. 7), this indicates that the user continues to watch the television program being broadcast. At this time, the control unit 3 Control goes to step SP22.

  In step SP22, the control unit 3 determines whether or not to end the reproduction of the television program. If a negative result is obtained here, this indicates that the user is continuously watching the television program being broadcast. At this time, the control unit 3 returns to step SP21 again.

  On the other hand, if an affirmative result is obtained in step SP22, this indicates that the user has finished viewing the television program being broadcast. At this time, the control unit 3 moves to the next step SP23 and performs digital processing. The noise correction processing procedure RT2 is finished.

  By such digital noise correction processing procedure RT2, the program recording / reproducing apparatus 1 in the second embodiment corrects digital noise of a television program.

(2-5) Operation and Effect in Second Embodiment In the above configuration, the control unit 3 of the program recording / playback apparatus 1 allows the user to view the television program being broadcast received by the receiving unit 10 when the user views the EPG decoder. 17, EPG information EI is acquired from the EPG information packet PE, and resolution information DI is acquired by analyzing the video signal SV by the resolution acquisition unit 24 B of the digital noise detection unit 24.

  Further, the control unit 3 of the program recording / playback apparatus 1 uses the EPG decoder 17 to obtain an average bit rate ABR corresponding to the program bit rate PBR and the resolution information DI from the EPG database DB of the hard disk drive 23.

  Further, the control unit 3 of the program recording / playback apparatus 1 uses the EPG decoder 17 to generate digital noise that is expected to be generated when the television program is decoded according to the average bit rate ABR and the resolution information DI. Is estimated.

  Further, the control unit 3 of the program recording / playback apparatus 1 uses the EPG decoder 17 to obtain noise correction amount information NR corresponding to the digital noise generation amount from the noise correction amount database of the hard disk drive 23.

  Further, the control unit 3 of the program recording / playback apparatus 1 causes the digital noise in the video signal SV to be detected by the noise position detection unit 24C of the digital noise detection unit 24 according to the average bit rate ABR, resolution information DI, and noise correction amount information NR. The generated noise generation position NP is detected.

  Then, the control unit 3 of the program recording / playback apparatus 1 corrects digital noise generated when the video signal SV is decoded by the video signal processing unit 18 according to the noise generation position NP and the noise correction amount information NR.

  Therefore, the program recording / playback apparatus 1 estimates the digital noise generation amount from the average bit rate ABR accumulated as a result of the user viewing other television programs in the past during the broadcasting of the television program having a predetermined resolution, Since the noise correction amount information NR corresponding to the digital noise generation amount is acquired, it is possible to correct the digital noise after specifying the noise generation position NP where the digital noise is likely to occur in the video signal SV.

  As a result, the program recording / playback apparatus 1 can determine whether the amount of digital noise generated during a broadcast of a television program having a predetermined resolution changes, for example, in response to the channel of the television program being switched by the user. The digital noise can be appropriately corrected with the noise correction amount information NR corresponding to the digital noise generation amount without causing the digital noise to remain insufficient or to be overcorrected to deteriorate the image quality.

  Further, the program recording / playback apparatus 1 subdivides and associates the EPG information EI broadcast station, time zone, genre, title, and the like when accumulating the average bit rate ABR as a result of viewing other television programs in the past. Since the average bit rate ABR is accumulated from the above, when obtaining the average bit rate ABR according to the EPG information EI of the television program being reproduced, it is possible to increase variations in obtaining the average bit rate ABR.

  As a result, for example, the program recording / playback apparatus 1 preferentially obtains the average bit rate ABR, which is assumed to be able to correct digital noise more appropriately, so that the priority order of the EPG information EI is “time zone and title → By setting such as “title → genre → time zone → broadcast station”, digital noise can be preferentially acquired from the average bit rate ABR that is assumed to be more appropriately corrected, and thus digital noise can be obtained. It can correct more appropriately.

  Furthermore, the program recording / playback apparatus 1 stores the average bit rate accumulated as a result of viewing other television programs in the past according to the EPG information EI (in this case, broadcast station, time zone, genre, title, etc.) of the television program. Since ABR is acquired and digital noise is corrected, it is not necessary to always acquire the bit rate BR of a television program being broadcast and correct the digital noise. It can be corrected by processing.

  According to the above configuration, the program recording / reproducing apparatus 1 generates the video signal SV by decoding the encoded video data MD obtained by compressing and encoding the television program, acquires the EPG information EI of the television program, The average bit rate ABR corresponding to the acquired EPG information EI is obtained from the average bit rate ABR stored in the EPG database DB of the hard disk drive 23 as a result of viewing other television programs, and the television program is compressed and encoded. The average value acquired from the noise correction amount database of the hard disk drive 23 that stores the noise correction amount information NR for correcting the digital noise accompanying with the average bit rate ABR in the encoded video data MD after the compression encoding is stored. Obtains noise correction amount information NR according to bit rate ABR Since the digital noise included in the video signal SV is corrected based on the noise correction amount information NR, the digital noise of the digital noise included in the video signal SV is determined from the bit rate BR of the encoded video data MD. Since the generation amount can be estimated, the digital noise can be corrected with the noise correction amount information NR corresponding to the digital noise generation amount, and thus the digital noise can be appropriately corrected.

(3) Other Embodiments In the first embodiment described above, the program recording / playback apparatus 1 always detects the bit rate BR and corrects the digital noise in accordance with the change in the bit rate BR. However, the present invention is not limited to this, and the bit rate BR detected during a predetermined time (for example, 10 seconds) is averaged, and the digital noise is corrected according to the averaged bit rate BR. Hysteresis processing (or buffer processing) was performed so that it is determined that the bit rate BR has changed when the bit rate BR has increased by a predetermined percentage or more (or decreased by a predetermined percentage or more) than the current rate. The digital noise may be corrected as described above. By doing so, the program recording / playback apparatus 1 changes the bit rate BR when, for example, the television program bit rate BR changes drastically in a television program such as a sports program. Although we intend to correct the digital noise at the same time (that is, in accordance with the change in the amount of digital noise generated), we cannot follow the change in the bit rate BR, and the digital noise is left too much or the correction is insufficient It is possible to avoid situations such as image quality degradation as much as possible.

  In the second embodiment described above, the program recording / playback apparatus 1 uses the entire program DB1, the time zone database DB2, the genre database DB3, the title database DB4, and the detected program bit rate PBR according to the EPG information EI. Although the case where the time zone title database DB5 is subdivided and accumulated has been described, the present invention is not limited to this, and the EPG database DB may be of any kind, number, and combination, and in short, the EPG information EI For example, the program bit rate PBR may be stored in a day of the week database for each day of the week.

  Furthermore, in the second embodiment described above, the program recording / reproducing apparatus 1 has described the case where the bit rate accumulation processing and the digital noise correction processing are performed in parallel. However, the present invention is not limited to this, The bit rate accumulation process may be completed at an arbitrary timing after viewing the television program. By doing so, the program recording / playback apparatus 1 can reduce the processing load related to the playback of the television program by the amount that the bit rate accumulation process and the digital noise correction process are not performed in parallel.

  Furthermore, in the second embodiment described above, the program recording / playback apparatus 1 obtains the program bit rate PBR by acquiring and averaging the bit rate BR of the encoded video data MD at a time interval of about 5 minutes. Although the case of acquiring is described, the present invention is not limited to this, and the time interval for acquiring the bit rate BR may be any number of minutes.

  Furthermore, in the second embodiment described above, the program recording / playback apparatus 1 stores the EPG database DB (in this case, the entire database DB1, the time zone database DB2, the genre database DB3, the title database DB4, and the time zone title database DB5). On the other hand, the case where the average bit rate ABR and the number of viewing programs is stored has been described. However, the present invention is not limited to this, and the total addition value of program bit rates PBR for the number of viewing programs up to that point (that is, The integrated value of the program bit rate PBR and the number of viewing programs) may be stored in the EPG database DB together with the average bit rate ABR and the number of viewing programs. By doing so, the program recording / reproducing apparatus 1 accumulates the program bit rate PBR (average bit rate) as much as it is not necessary to integrate the average bit rate ABR and the number of viewing programs every time the program bit rate PBR is newly acquired. The amount of processing related to ABR update can be reduced (conversely, the program recording / playback apparatus 1 stores only the average bit rate ABR and the number of viewing programs in the EPG database DB as in the second embodiment described above. In this case, it is not necessary to use the storage area of the hard disk drive 23 as much as it is not necessary to store the total addition value).

  Further, in the first and second embodiments, the data providing apparatus 1 determines whether the resolution of the video signal SV is a resolution corresponding to SDTV (640 × 480) or a resolution corresponding to HDTV (1920 × 1080). Although the case where discrimination is made has been described, the present invention is not limited to this, and the resolution according to SDTV may not be (640 × 480), and the resolution according to HDTV is not (1920 × 1080). In the first place, the resolution may not conform to SDTV or HDTV, and the resolution of the video signal SV may be anything. In that case, the program recording / reproducing apparatus 1 prepares a noise correction amount database for storing the noise correction amount information NR in advance corresponding to the resolution, so that it is the same as in the first and second embodiments described above. An effect can be obtained.

  Furthermore, in the first and second embodiments described above, the program recording / playback apparatus 1 performs noise correction including threshold values (that is, block noise threshold value and mosquito noise threshold value) corresponding to the digital noise generation amount estimated from the bit rate. Although the case where the quantity information NR is used for digital noise correction has been described, the present invention is not limited to this, and the coefficient or function used when correcting the luminance of each pixel in the video signal processing unit 18 is a bit. It may be prepared according to the rate (that is, the digital noise generation amount), and may be included in the noise correction amount information NR and used for digital noise correction. By doing so, the program recording / reproducing apparatus 1 corrects the digital noise using a coefficient or a function corresponding to the bit rate (that is, the amount of digital noise generated) when the video signal processing unit 18 corrects the digital noise. The digital noise can be corrected more appropriately than the digital noise is corrected using a fixed coefficient or function.

  Further, in the first and second embodiments described above, the program recording / playback apparatus 1 indicates that the luminance difference value is indicated by the noise correction amount information NR at the boundary between the rectangular blocks on the video corresponding to the video signal SV. Although the case where the boundary exceeding the block noise threshold is detected as the noise occurrence position NP where the block noise occurs has been described, the present invention is not limited to this, and the noise occurrence position NP where the block noise occurs can be detected. In this case, the detection method is not particularly limited. Further, it is assumed that block noise occurs at all the boundaries of the rectangular blocks on the video corresponding to the video signal SV without detecting the noise generation position NP, and the noise correction amount information NR indicates all the boundaries. Correction according to the block noise threshold may be performed, and the method of correcting digital noise related to block noise is not particularly limited.

  Furthermore, in the first and second embodiments described above, the program recording / playback apparatus 1 has a luminance difference value indicated by the noise correction amount information NR among a plurality of rectangular blocks constituting a video corresponding to the video signal SV. The case where the rectangular block having pixels exceeding the mosquito noise threshold is detected as the noise generation position NP where the mosquito noise is generated has been described. However, the present invention is not limited to this, and the noise generation position where the mosquito noise occurs. As long as NP can be detected, the detection method is not particularly limited. Further, it is assumed that mosquito noise is generated in all pixels on the video corresponding to the video signal SV without detecting the noise generation position NP, and the mosquito noise threshold value indicated by the noise correction amount information NR for all of the pixels. Correction according to the mosquito noise may be performed, and the digital noise correction method for mosquito noise is not particularly limited.

  Further, in the first and second embodiments described above, the program recording / reproducing apparatus 1 detects block noise and mosquito noise as digital noise and corrects them, but the present invention has been described. However, the present invention is not limited to this, and only one of block noise and mosquito noise may be detected and corrected as digital noise.

  Furthermore, in the first and second embodiments described above, the program recording / playback apparatus 1 uses the noise correction amount database NR of the hard disk drive 23 to obtain the noise correction amount information NR corresponding to the bit rate BR (including the average bit rate ABR). However, the present invention is not limited to this, and the noise correction amount information NR corresponding to the bit rate BR (including the average bit rate ABR) is included in the bit rate BR (including the average). It may be calculated in real time when the bit rate (ABR) is acquired. By doing so, the program recording / reproducing apparatus 1 can secure the storage area of the hard disk drive 23 as much as it is not necessary to prepare the noise correction amount database in advance.

  Further, in the first and second embodiments described above, the case where the present invention is applied to the program recording / playback apparatus 1 for recording and playing back a television program has been described. However, the present invention is not limited to this. For example, it is connected to a television device having a television broadcast receiving function and a display means such as a liquid crystal panel, a television receiver such as a so-called set top box, a video content streaming distribution server or a video server, etc. The present invention may be applied to a content player that receives and reproduces video content. In this case, for example, a predetermined content reproduction program may be executed in an information processing apparatus such as a personal computer or a mobile phone.

Furthermore, in the first and second embodiments described above, the program recording / playback apparatus 1 corrects digital noise when decoding encoded video data compressed and encoded by the MPEG2-Video system. Although the present invention is not limited to this, the present invention is not limited to this, and any other compression encoding system that generates digital noise during decoding, such as WMV (Windows (registered trademark) Media Video), RealVideo, Divx, etc. Digital noise generated when decoding encoded video data that has been compression-encoded by the above-described compression-encoding method may be corrected, and even in this case, the same as in the first and second embodiments described above The effect of can be obtained.

  Furthermore, in the first and second embodiments described above, the hard disk drive 23 as the correction information storage unit, the video decoder 15 as the decoding processing unit, and the digital noise detection unit 24 or EPG as the bit rate acquisition unit. Decoder 17, digital noise detection unit 24 or EPG decoder 17 as a correction information acquisition unit, video signal processing unit 18 as a video correction unit, reception unit 10 as a reception unit, and EPG decoder as an attribute information extraction unit 17, the hard disk drive 23 as a bit rate storage unit, the EPG decoder 17 as a bit rate update unit, and the resolution acquisition unit 24 B as a resolution acquisition unit constitute a program recording / playback apparatus 1 as a video correction device. Although the case has been described, the present invention is not limited to this, and other various A correction information storage unit having a circuit configuration, a decoding processing unit, a bit rate acquisition unit, a correction information acquisition unit, a video correction unit, a reception unit, an attribute information extraction unit, a bit rate storage unit, and a bit You may make it comprise a video correction apparatus by a rate update part and a resolution acquisition part.

  Furthermore, the present invention is not limited to the first and second embodiments described above and the other embodiments described so far, but the embodiments described above and the other embodiments described so far. The scope of application also extends to forms in which some or all of the above are arbitrarily combined, or forms in which some are extracted.

  The present invention is suitable for application to a program playback apparatus that plays back a broadcast television program.

It is a block diagram which shows the circuit structure of a program recording / reproducing apparatus. It is a block diagram which shows the mode of the correction | amendment of the digital noise by 1st Embodiment. It is a flowchart which shows the procedure of the digital noise correction process by 1st Embodiment. It is a block diagram which shows the mode of the correction | amendment of the digital noise by 2nd Embodiment. It is a basic diagram which shows the mode of accumulation | storage of the program bit rate with respect to an EPG database. It is a flowchart (1) which shows the procedure of the digital noise correction process by 2nd Embodiment. It is a flowchart (2) which shows the procedure of the digital noise correction process by 2nd Embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Program recording / reproducing apparatus, 2 ... Monitor apparatus, 3 ... Control part, 4 ... CPU, 5 ... ROM, 6 ... RAM, 7 ... System bus, 8 ... Remote controller, 9 ... Input Interface: 10: Receiver, 11: Tuner, 12: Demodulator, 13: Descrambler, 14: Demultiplexer, 15: Video decoder, 16: Audio decoder, 17: EPG decoder, 18... Video signal processor, 19... Display panel, 20. Audio signal processor, 21. Speaker, 22. Hard disk drive interface, 23. Hard disk drive, 24. Digital noise detector, 24 a. ... Bit rate acquisition unit 24, 24B ... Resolution acquisition unit, 24C ... Noise position detection unit, ABR ... Average bit rate, BR ... Bit rate, BR: Program bit rate, DA: Digital audio signal, DI: Resolution information, EI: EPG information, MD: Encoded video data, NP: Noise occurrence position, NR: Noise correction amount information, PA ... Audio data packet, PE ... EPG information packet, PV ... Video data packet, SV ... Video signal, SA ... Output audio signal, SVO ... Output video signal S, RT1, RT2 ... Digital noise correction processing procedure.

Claims (10)

A correction information storage unit that stores noise correction information for correcting digital noise associated with compression encoding of video content in association with the bit rate in the compression encoded video data after the compression encoding;
A decoding processing unit for generating decoded video content by decoding the compressed encoded video data;
A bit rate acquisition unit for acquiring a bit rate of the compressed encoded video data;
A correction information acquisition unit that acquires the noise correction information according to the bit rate acquired by the bit rate acquisition unit from the correction information storage unit;
A video correction unit that corrects the digital noise included in the decoded video content generated by the decoding processing unit based on the noise correction information acquired by the correction information acquisition unit. A video correction device. Receiving a television broadcast wave including the compressed encoded video data compressed and encoded as the video content of the television program, and extracting the compressed encoded video data from the television broadcast wave;
An attribute information extraction unit for extracting attribute information of the television program from the television broadcast wave;
A bit rate storage unit that stores the attribute information of the television program and the bit rate of the compression-encoded video data representing the television program in association with each other,
The bit rate acquisition unit
The video correction apparatus according to claim 1, wherein the bit rate according to the attribute information of the television program is acquired from the past bit rates stored in the bit rate storage unit. . A bit rate for updating the bit rate stored in the bit rate storage unit corresponding to the attribute information of the television program based on the bit rate of the television program when the television program is received The video correction device according to claim 2, further comprising: an update unit. The above attribute information
It is characterized by comprising at least one or more information among broadcast station information for broadcasting the television program, broadcast time zone information for the television program, genre information for the television program, and title information for the television program. The video correction apparatus according to claim 2. The correction information storage unit
Storing noise specifying information for specifying presence / absence and generation position of the digital noise in the decoded video content as the noise correction information;
The noise information acquisition unit
The noise specifying information corresponding to the bit rate acquired by the bit rate acquisition unit is acquired from the correction information storage unit,
The video correction unit
The presence / absence and occurrence position of the digital noise included in the decoded video content are identified and corrected based on the noise identification information acquired by the noise information acquisition unit. The video correction apparatus described in 1. The correction information storage unit
A threshold value representing a difference in luminance between pixels is stored as the noise specifying information,
The video correction unit
Among the pixels constituting the decoded video content, the presence or absence of the digital noise is specified in response to the difference in luminance between adjacent pixels being equal to or greater than the threshold, and the pixels constituting the decoded video content The video correction apparatus according to claim 5, wherein a position where a difference in luminance between adjacent pixels is equal to or greater than the threshold is specified and corrected as the generation position of the digital noise. A resolution acquisition unit for acquiring the resolution of the decoded video content,
The correction information storage unit
Storing the noise correction information for each resolution of the video content;
The correction information acquisition unit
The noise correction information according to the bit rate acquired by the bit rate acquisition unit and the resolution acquired by the resolution acquisition unit is acquired from the correction information storage unit. The image correction apparatus described. The bit rate acquisition unit
The video correction apparatus according to claim 1, wherein the bit rate is acquired by measuring an actual bit rate in the compressed video data. A decoding step of generating decoded video content by decoding compressed encoded video data obtained by compression encoding video content;
A bit rate acquisition step of acquiring a bit rate of the compressed encoded video data;
The correction information storage unit that stores noise correction information for correcting digital noise associated with compression encoding of the video content in association with the bit rate in the compression encoded video data after the compression encoding is acquired from the correction information storage unit A noise correction information acquisition step of acquiring the noise correction information according to the bit rate;
And a video correction step of correcting the digital noise included in the decoded video content based on the noise correction information. Against the computer
A decoding step of generating decoded video content by decoding compressed encoded video data obtained by compression encoding video content;
A bit rate acquisition step of acquiring a bit rate of the compressed encoded video data;
The correction information storage unit that stores noise correction information for correcting digital noise associated with compression encoding of the video content in association with the bit rate in the compression encoded video data after the compression encoding is acquired from the correction information storage unit A noise correction information acquisition step of acquiring the noise correction information according to the bit rate;
A video correction program for executing a video correction step of correcting the digital noise included in the decoded video content based on the noise correction information.

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